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Canonne, Clément L. [VerfasserIn]; Grigorescu, Elena [VerfasserIn]; Guo, Siyao [VerfasserIn]; Kumar, Akash [VerfasserIn]; Wimmer, Karl [VerfasserIn] ; Clément L. Canonne and Elena Grigorescu and Siyao Guo and Akash Kumar and Karl Wimmer [MitwirkendeR]

Testing k-Monotonicity

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  • Medientyp: E-Artikel; Sonstige Veröffentlichung; Elektronischer Konferenzbericht
  • Titel: Testing k-Monotonicity
  • Beteiligte: Canonne, Clément L. [VerfasserIn]; Grigorescu, Elena [VerfasserIn]; Guo, Siyao [VerfasserIn]; Kumar, Akash [VerfasserIn]; Wimmer, Karl [VerfasserIn]
  • Erschienen: Schloss Dagstuhl – Leibniz-Zentrum für Informatik, 2017
  • Sprache: Englisch
  • DOI: https://doi.org/10.4230/LIPIcs.ITCS.2017.29
  • Schlagwörter: Property Testing ; Learning ; Monotonicity ; Boolean Functions
  • Entstehung:
  • Anmerkungen: Diese Datenquelle enthält auch Bestandsnachweise, die nicht zu einem Volltext führen.
  • Beschreibung: A Boolean k-monotone function defined over a finite poset domain D alternates between the values 0 and 1 at most k times on any ascending chain in D. Therefore, k-monotone functions are natural generalizations of the classical monotone functions, which are the 1-monotone functions. Motivated by the recent interest in k-monotone functions in the context of circuit complexity and learning theory, and by the central role that monotonicity testing plays in the context of property testing, we initiate a systematic study of k-monotone functions, in the property testing model. In this model, the goal is to distinguish functions that are k-monotone (or are close to being k-monotone) from functions that are far from being k-monotone. Our results include the following: 1. We demonstrate a separation between testing k-monotonicity and testing monotonicity, on the hypercube domain {0,1}^d, for k >= 3; 2. We demonstrate a separation between testing and learning on {0,1}^d, for k=\omega(\log d): testing k-monotonicity can be performed with 2^{O(\sqrt d . \log d . \log{1/\eps})} queries, while learning k-monotone functions requires 2^{\Omega(k . \sqrt d .{1/\eps})} queries (Blais et al. (RANDOM 2015)). 3. We present a tolerant test for functions f\colon[n]^d\to \{0,1\}$with complexity independent of n, which makes progress on a problem left open by Berman et al. (STOC 2014). Our techniques exploit the testing-by-learning paradigm, use novel applications of Fourier analysis on the grid [n]^d, and draw connections to distribution testing techniques. Our techniques exploit the testing-by-learning paradigm, use novel applications of Fourier analysis on the grid [n]^d, and draw connections to distribution testing techniques.
  • Zugangsstatus: Freier Zugang